Enhancing Hole Mobility in Monolayer WSe2 p-FETs via Process-Induced Compression

Abstract

Understanding the interactions between strain, interfacial mechanics, and electrical performance is critical for designing beyond silicon electronics based on hetero-integrated 2D materials. Through combined experiment and simulation, we demonstrated and analyzed the enhancement of hole mobility in p-type monolayer WSe2 field effect transistors (FETs) under biaxial compression. We tracked FET performance versus strain by incrementing compressive strain to WSe2 channels via sequential AlOx deposition and performing intermediate photoluminescence and transport measurements. The hole mobility factor increased at a rate of 340 95 %/%ε, and the on-current factor increased at a rate of 460 340 %/%ε. Simulation revealed that the enhancement under compression arises primarily from a reduction in inter-valley scattering between the --K valence bands, and the rate is robust against variations in carrier density, impurity density, or dielectric environment. These findings show that compressive strain is a powerful technique for enhancing performance in 2D p-FETs and that it is multiplicative with defect and doping engineering.

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